Technical Papers Archives - International Lightning Protection Association
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Technical Papers

The relationship between pollution and lightning incidence has long been pointed out by many experts, but an unexpected situation allowed a great step forward in the study of this theory: WHO (World Health Organisation) recognized in March 2020 the SARS-CoV-2 coronavirus infections as a pandemic. In response to this situation, several countries decreed lockdowns to ensure social distancing. The result of the mobility restrictions was a decrease in emissions of air pollutants which enabled researchers to analyse in detail the influence of aerosols in lightning incidence both in Brazil and Italy. The group of Pinto Neto chose two large cities in Brazil, São Paulo and Belo Horizonte, from 20 March to 2 April 2020. The authors found an important decrease in pollution in that period compared with the data obtained in previous years (from 2015 to 2020). Moreover, the percentage of cloud-to-ground lightning was lower than the values from previous years in São Paulo, while in Belo Horizonte was significantly higher. Therefore, the study showed the strong influence of pollution on lightning characteristics and that this influence could change depending on the city and the pollutant concentration. On the other hand, the lockdown decreed in Italy extended from 9 March to 18 May 2020, followed by a long period of de-escalation of the mobility restrictions. This period coincided with a 70% decrease in lightning activity in the Po valley. The Po Valley is a highly industrialized region, characterized by high lightning incidence due to certain meteorological features like the proximity to mountains, the humidity flow from the sea and the convergence of cold and warm air masses. The poor ventilation conditions in the valley, bundled with low temperatures, promote the permanence of aerosols for long duration. However, during the lockdown, there was a drastic reduction in the industrial activity, traffic and rail transport which led to a substantial decrease in the concentration of aerosols. The authors of this work used different models to estimate which percentage of the reduction could be attributed to the reduction in pollutants emission. Their calculations showed that about 36% came from the decreased pollution in the Po valley. These two studies support the hypothesis of an impact of anthropogenic aerosols on lightning activity. Ultimately, this statement should be considered for the optimization of lightning prediction in global climate models, as well as in the prediction of forest fires caused by lightning. References Pinto Neto, O., Pinto, I. R. C. A. & Pinto, O. Lightning during the COVID-19 pandemic in Brazil. J. Atmos. Solar-Terrestrial Phys. 211, 105463 (2020). Pérez-Invernón, F. J., Huntrieser, H., Gordillo-Vázquez, F. J. & Soler, S. Influence of the COVID-19 lockdown on lightning activity in the Po Valley. Atmos. Res. 263, (2021)....

Some may say that Early Streamer Emission (ESE) technology suffers from lack of experience. The main argument is the location of the ESE historic and prominent manufacturers: they are based in Western Europe with low lightning density compared to the other regions in the world (see https://interactive-lightning-map.vaisala.com/). The explanation is rather simple: France and Spain where the first countries releasing a proper ESE standards (namely NF C 17 102 and UNE 21 186), then followed by several other countries. But this is a fact: these two countries, with Ng density of 3 on average, are far from the most lightning prone areas worldwide: more than 40 in South East Asia, Central Africa or Central America. The first hint came from two lightning high density countries: Malaysia has an average lightning density of 51.9 event/km²/year. A survey has been released in 2016 (conducted by Mega Jati institute on behalf of ST group, available here: Part 1 & Part 2): the percentage of buildings with lightning damages stands at 7.18% for meshed cage/single rods protected buildings vs 4.68% for ESE protected buildings. With a 60.1 event/km²/year, Cuba also stands as at a very high rate of lightning probability. In 2021, the local government agency APCI released a technical paper based on 20 years of ESE rods installation across the country. The “failure rates” of ESE installations is 0.2% whereas it reaches 0.59% for other lightning protection systems. In both cases, the rate of incidents / damages is lower for the ESE lightning protection systems. The ILPA is also working on another statistical survey to assess the geographic distribution of ESE installations worldwide: what is the percentage of ESE rods installed in high-density areas (Ng > 10 event/km²/year) compared with lower ones. We will soon release this data on ILPA website. Stay tuned !...